Asko Simojoki scite author profile

Agriculture is one of the largest contributors of the anthropogenic greenhouse gases (GHGs) responsible for global warming. Measurements of gas fluxes from dung pats suggest that dung is a source of GHGs, but whether these emissions are modified by arthropods has not been studied. A closed chamber system was used to measure the fluxes of carbon dioxide (CO2), methane (CH4) and nitrous oxide (N2O) from dung pats with and without dung beetles on a grass sward. The presence of dung beetles significantly affected the fluxes of GHGs from dung pats. Most importantly, fresh dung pats emitted higher amounts of CO2 and lower amounts of CH4 per day in the presence than absence of beetles. Emissions of N2O showed a distinct peak three weeks after the start of the experiment – a pattern detected only in the presence of beetles. When summed over the main grazing season (June–July), total emissions of CH4 proved significantly lower, and total emissions of N2O significantly higher in the presence than absence of beetles. While clearly conditional on the experimental conditions, the patterns observed here reveal a potential impact of dung beetles on gas fluxes realized at a small spatial scale, and thereby suggest that arthropods may have an overall effect on gas fluxes from agriculture. Dissecting the exact mechanisms behind these effects, mapping out the range of conditions under which they occur, and quantifying effect sizes under variable environmental conditions emerge as key priorities for further research.

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Driver-Pressure-State-Impact-Response (DPSIR) Analysis and Risk Assessment for Soil Compaction—A European Perspective

Schjønning¹,

Akker²,

Keller³

et al. 2015

140

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Contribution of nitrification and denitrification to N₂O production in peat, clay and loamy sand soils under different soil moisture conditions

Pihlatie

Syväsalo

Simojoki

et al. 2004

Nutrient Cycling in Agroecosystems

137

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Treating cattle with antibiotics affects greenhouse gas emissions, and microbiota in dung and dung beetles

et al. 2016

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Antibiotics are routinely used to improve livestock health and growth. However, this practice may have unintended environmental impacts mediated by interactions among the wide range of micro-and macroorganisms found in agroecosystems. For example, antibiotics may alter microbial emissions of greenhouse gases by affecting livestock gut microbiota. Furthermore, antibiotics may affect the microbiota of non-target animals that rely on dung, such as dung beetles, and the ecosystem services they provide. To examine these interactions, we treated cattle with a commonly used broad-spectrum antibiotic and assessed downstream effects on microbiota in dung and dung beetles, greenhouse gas fluxes from dung, and beetle size, survival and reproduction. We found that antibiotic treatment restructured microbiota in dung beetles, which harboured a microbial community distinct from those in the dung they were consuming. The antibiotic effect on beetle microbiota was not associated with smaller size or lower numbers. Unexpectedly, antibiotic treatment raised methane fluxes from dung, possibly by altering the interactions between methanogenic archaea and bacteria in rumen and dung environments. Our findings that antibiotics restructure dung beetle microbiota and modify greenhouse gas emissions from dung indicate that antibiotic treatment may have unintended, cascading ecological effects that extend beyond the target animal.

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Gas concentration driven fluxes of nitrous oxide and carbon dioxide in boreal forest soil

et al. 2007

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A B S T R A C T Nitrous oxide (N 2 O) and carbon dioxide (CO 2 ) fluxes were measured in a boreal forest during two growing seasons with soil gradient and chamber methods. N 2 O fluxes obtained by these two techniques varied from small emission to small uptake. N 2 O fluxes were of the same order of magnitude, however, the fluxes measured by the soil gradient method were higher and more variable than the fluxes measured with chambers. The highest soil gradient N 2 O fluxes were measured in the late summer and the lowest in the autumn and spring. In the autumn, litter fall induced a peak in N 2 O concentration in the organic O-horizon, whereas in the spring N 2 O was consumed in the O-horizon. Overall, the uppermost soil layer was responsible for most of the N 2 O production and consumption. Soil gradient and chamber methods agreed well with CO 2 fluxes. Due to the very small N 2 O fluxes and the sensitivity of the flux to small concentration difference between the soil and the ambient air, the flux calculations from the O-horizon to the atmosphere were considered unreliable. N 2 O fluxes calculated between the soil A-and O-horizons agreed relatively well with the chamber measurements.

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Asko Simojoki

Quantifying Beetle-Mediated Effects on Gas Fluxes from Dung Pats

Driver-Pressure-State-Impact-Response (DPSIR) Analysis and Risk Assessment for Soil Compaction—A European Perspective

Contribution of nitrification and denitrification to N₂O production in peat, clay and loamy sand soils under different soil moisture conditions

Treating cattle with antibiotics affects greenhouse gas emissions, and microbiota in dung and dung beetles

Gas concentration driven fluxes of nitrous oxide and carbon dioxide in boreal forest soil

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Asko Simojoki

Quantifying Beetle-Mediated Effects on Gas Fluxes from Dung Pats

Driver-Pressure-State-Impact-Response (DPSIR) Analysis and Risk Assessment for Soil Compaction—A European Perspective

Contribution of nitrification and denitrification to N2O production in peat, clay and loamy sand soils under different soil moisture conditions

Treating cattle with antibiotics affects greenhouse gas emissions, and microbiota in dung and dung beetles

Gas concentration driven fluxes of nitrous oxide and carbon dioxide in boreal forest soil

Contact Info

Product

Resources

About

Contribution of nitrification and denitrification to N₂O production in peat, clay and loamy sand soils under different soil moisture conditions